Electrical generating station



Oct. 24, 1944. A. c. MONTEITH 2,361,229.

ELECTRICAL GENERATING STATION Filed March 13, 1943 2 Sheets-Sheet 1 9 WITNESSES: v if INVENTOR {24. Z 3 l; f7/ex'anaer6flan/efib.

. 2 l9} i'iRNEY I Oct. 24, 1944. I A. c. MQNTEITH 2,361,229

ELECTRICAL GENERATING STATION Filed March 11 3, 1943 2 Sheets-Sheet 2 Hy: 4. P

YWETNESSES: INVENTOR 554W 4 /7/exan 04?," CMonfaf/Z ATTORNEY Patented a; 24, 1944 UNITED STATES PATENT OFFICE ELECTRICAL GENERATING STATION Alexander C. Monteitb, Wilkinsburg, Pm, assignor to Westinghouse'Elech-ic & Manufacturin; Company, East Pittsburgh, Pa., a corporaof electrical power.

tion of Pennsylvania 14 Claims.

This invention relates to electrical systems, and it has particular relation to systems for supplying electrical energy to auxiliary equipment in electrical generating stations.

Because of the importance of insuring continuous operation of equipment in electrical generating stations, extreme care is taken in the design of such stations. Much auxiliary equipment in electrical generating stations, such as draft fans and stokers, is operated by means of electrical motors. Some of the auxiliary equipment as boiler feed pumps, draft fans, unit type pulverizers, etc. may be termed essential auxiliary equipment. Electrical service to essential auxiliary equipment cannot be interrupted even for a fraction of a minute.

In accordance with the invention, auxiliary equipment in an electrical generating system is supplied with electrical energy through a network system. This network system includes a load circuit which may bein the form of a mesh grid circuit;'a loop circuit, or a load bus which is energized through one or more feeder circuits connected to each of the electrical generators in the generating station or to other sources Connection of the feeder circuits to the load bus or other circuit employed for supplying electrical energy to theauxiliary equipment may be effected through network protectors which trip to disconnect each feeder circuit from the load bus in response to a fault on the feeder circuit.

When two or more electrical generators are connected to a power bus, synchronizing currents flow through the power bus, to maintain synchronism between the generators. To avoid synchronization of the generators through the load bus, the invention contemplates further an interlocking of the network protectors employed for connecting the'feeder circuits to the. load bus to prevent closure of the network protectors unless the-associated electrical generator is connected to its power bus.

It is, therefore, an object of the invention to provide an improved system for supplying electrlcal energy to auxiliary equipment in electrical generating stations.

It is' a further object of the invention to provide an electrical generating station having a plurality of electrical generators associated with a power bus, with' a load bus connected to each of the generators through a separate feeder circult, and with means forpreventing connection of each feeder circuit to the load bus unless the associated electrical generator is connected to its power bus.

Other objects of the invention will be apparent from the following description taken in connection with the accompanying drawings, in.

which:

Figure 1 is a schematic view in single line of an electrical system embodying the invention;

Fig. 2 is a schematic view in greater detail showing a portion of the system in Fig. 1;

Figs. 3 and 4 are schematic views in single line showing modifications of. the system illustrated in Fig. l; and

single phase or polyphase operation, andit'may be designed for operation at various frequencies.

The power bus ll may be connected to other electrical systems through one or more connecting circuits H each having a circuit interrupter l3 associated therewith for controlling the connection of the connecting circuit to the power bus 5. This connectin circuit ll may be designed to transmit electrical energy from the power bus 5 or toward the power bus. The connection of the electrical generators l and 3 to the power bus 5 are controlled, respectively, by

circuit interrupters l5 and I1.

. As previously pointed out, electrical generating stations have associated therewith various auxiliary equipment which must be supplied with electrical energy. For this purpose, a load circuit is provided which may be in the form of a mesh grid circuit, a loop circuit, or a load bus. For the purpose of discussion, it is assumed that a load bus I! is provided. Theauxiliary equip- P ment represented by loads 2| may beconnected for energizatlon from the load bus I! through suitable circuit interrupters 23.

Electrical energy is supplied to the load bus l9 through oneor more feeder circuits associated with each of the electrical generators. In Fig. 1, a feeder circuit 2| is associated with the electrlcal generator I, and a feeder circuit 21 is associated with the electrical generator 3. Each of the feeder circuits is connected to the load bus through one or more transformers, which may be termed network transformers 28, and network protectors 3 I. The construction of the network protectors 3| may vary appreciably. For example, the network protector may include a circuit interrupter controlled by relays to trip in response to a reversal in the normal direction of current fiow therethrough. The circuit interrupter is also controlled to close when the voltage and phase relationships across its poles are such as to assure the direction of current flow from theassociated network transformer 29 to the load bus IS. A network protector of this type is disclosed in the Parsons Patent 1,997,697.

To remove a faulty feeder circuit from service without interrupting the operation of the remainder of the electrical system, each of the feeder circuits may, if desired, be provided with a feeder-circuit-interrupter .33 which may be designed to trip when current flowing therethrough exceeds a predetermined value.

In the system illustrated in Fig. l, the electrical generators I and 3 are intended to be synchronized through the power bus 5. In order to prevent synchronization of the generators through the load bus is, the network protectors 3| associated with each feeder circuit may be interlocked with the associated circuit interrupters I5 and I! to remain in closed position only when the associated circuit interrupter IE or II is in closed condition. With such a construction, both of the circuit interrupters I5 and I! must be closed before their associated network protectors 3| can be closed. Consequently, complete synchronization of the generators I and 3 cannot take place through the load bus It.

If both of the electrical generators I and 3 are out of service, and it is desired to start thegenerating station, electrical energy for the auxiliary equipment must be supplied from a source other than the electrical generators. To this end, a feeder circuit 35 is provided which is connected at one end to the load bus I 8 through network transformers 29 and network protectors ii. The remaining end of the feeder circuit 35 is connected to the power bus 5 through a transformer 31 and a circuit interrupter l9.

Before proceeding with a detailed discussion of the component parts of the system illustrated in Fig. 1, a brief review of the operation of the system may prove to be helpful. Assuming that the electrical generators I and 3 are both out of service and that it is desired to start the generating station, the circuit interrupters I 3 and 35 are closed toenergize the feeder circuit 35. If the network protectors 3| associated with the feeder circuit 35 are of the automatic closing type, disclosed in the aforesaid Parsons patent, these protectors close to complete the connection of the load bus I9 to the power bus 5. Consequently, closure of the circuit interrupters 23 energizes the auxiliary equipment with electrical energy supplied by the connecting circuit II.

After the auxiliary equipment has been energized for a sufficient length of time, one of the generators, such as the generator I, may be brought up to its rated rate of rotation and connected to the power bus IS by closure of the circuit interrupter i5. Closure of the circuit interrupter it releases the interlock on the network protectors 3i associated with the feeder circuit 25 and permits closure of these network protec tors. Thereafter the Io'adbus I8 is energi through both of the feeder circuits 2 If a second generator is to b I the generator 3 is brought up I of rotation. It should be observed at this-point that even though the generator 3 is in condition to supply electrical energy to the remainder of the system, it cannot be connected to the load bus I9 through its feeder circuit 21 until the associated circuit interrupter I1 is closed to connect the generator to the power bus ii. For this reason, the generators I and 3 are not synchronized through the load bus I 9 alone, but are synchronized in the desired manner through the power bus 5. After closure of the circuit interrupter II, the interlock on the network protectors" 3% associated with the feeder circuit 2'! is released to permit connection of the feeder circult 21 to the load bus I9. Thereafter electrical energy is supplied to the load bus it through the three feeder circuits 25, 21 and 35.

Should a fault occur on one of the feeder circuits such as the feeder circuit 25, the direction of current flow through its associated network protectors reverses and flows from the load bus I! to the fault. Therefore, the network protectors 3i associated with the feeder circuit 25 trip to disconnect the feeder circuit from the load bus It. In addition, the feeder-circuit interrupter 33, if prov trips to complete the disconnection of the scarier circuit 25 from the remainder of the system. Consequently, the entire system, with the exception of the feeder circuit 25, continues in operation, and the load bus I9 receives electrical energy without interruption from the feeder circuits 21 and 35. In a similar manner, if a fault occurs on the feeder circuit 21, this feeder circuit is removed from service by operation of its associated network protectors 3| and circuit interrupter 33. Should a fault occur on the feeder circuit 35, tripping of the circuit interrupter 39 and of the network protectors 3| removes this feeder circuit from service. Since the general operation of the system now is understood, the portion of the system illustrated in detail in Fig. 2 may be considered.

In Fig. 2, the electrical system of Fig. 1 is represented as a three-phase system designed for operation at a suitable frequency such as cycles per second. As examples of voltages which may be encountered in practice, the generator may be designed to generate electrical energy at 13.2 kilovolts which is stepped up by the transformer I to a ph ase-to-phase voltage of 66 kilovolts. The transformer 29 may be designed to step down the voltage generated by the electrical generator I to a. phase-to-phase voltage of 460 volts. be of any desired type, they are illustrated as having delta-connected primary windings and star connected, grounded neutral secondary windings.

The circuit interrupter I5 which connects the transformer I to the power bus 6 may be of any suitable construction. As illustrated, the circuit interrupter includes'a. closing motor or solenoid M which may be energized in any conventional manner from any suitable source to close the circuit interrupter. In addition, the circuit interrupter includes a tripping solenoid This tripping solenoid may be connected for energizetion to a suitable source of energy of a relay Iii which is respo the embodiment or rig. talre the form n stcn rainy which is energised "i7 I Although the transformers I and 29 may II. The relay conveniently may be of the inverse-time-delay type. Although only one relay is illustrated associated with one phase conductor of the electrical system, it will be understood that additional relays and current transformers may b similarly associated with other phase conductors of the electrical system in a manner well understood in the art.

For controlling the connection of the feeder Y circuit 25 to the electrical generator I, the circuit interrupter 33 may be of any suitable construction such as that illustrated for the circuit interrupter I5. The circuit interrupters l1 and 3901' Fig. 1 may be similar to the circuit interrupter |5.

The network protector 3| includes a circuit interrupter 5| having a closing motor or solenoid 53 and a tripping solenoid 55. Energization of the closing solenoid 53 is effected by connecting the solenoid across two of the three phase conductors A, B and C, such as the phase conductors conductors B and C, and the secondary winding of the transformer 29, through a circuit including the front contacts of a closing relay 51. Back contacts of a pallet switch 59 which is operated by the circuit interrupter 5| are included in this circuit.

Closure and trpping of the circuit interrupter 5| may be controlled in part by a masterrelay 6| having closing contacts 53 and tripping contacts 65 positioned to be engaged selectively by a movable contact 61. The construction of the master relay is well understood in the art and may take the form of one of the master relays illustrated in the aforesaid Parsons patent. Such a relay may be designed to close its tripp ng contacts when the direction of energy flow through the poles of the circuit interrupter 5| reverses from its normal direction. Such reversal may take place when a fault occurs on the feeder circuit 25. Th master relay may be designed to clos its closing contacts 83 when the voltages across the poles of the circuit interrupter 5| is such that electrical energy will be supplied from the trans former 29 to the load bus l9.

As previously pointed out, the network protector 3| is interlocked with the circuit interrupter l5 to prevent the circuit interrupter 5| from being in its closed condition unless the circuit interrupter |5 is in its closed condition. For this purpose, the circuit interrupter l5 may be provided with a pallet switch 59 having front contacts 1| and back contacts 13. These front and back contacts are closed respectively when the circuit interrupter i5 is in its closed or open condition. The front contacts 1| of the pallet switch 59 are in series with the closing contact 99 of the master relay to prevent a closing operation of the circuit interrupter 5| unless both pairs of contacts are closed. Closure of both pairs of contacts completes an energizing circuit for the closing relay 51 which may be traced from the conductor B through a, conductor 15, the front contacts 1|, a conductor 11, the closing contacts 63, a conductor 19, a pallet switch 8| associated with the circuit interrupter 5|, a conductor 93, the energizing windingof the closing relay are connected in parallel. Closure of either pair of these contacts connects the tripping solenoid 55 of the circuit interrupter 5| across the B and C. The solenoid is connected to the phase phase conductors B and C through a pallet switch 91 associated with the circuit interrupter 5|.

From this discussion of the interlocking connections between the circuit interrupters l5 and 5|, it will be appreciated that if the'circuit interrupter i5 is in open condition, the circuit interrupter 5| cannot be closed. After the circuit interrupter l5 has been operated to closed condition, the circuit interrupter'5l is also closed, provided the voltage conditions across its poles are such as to actuate the movable contact 91 of the master relay into engagement with the closing contacts 53 thereof. circuit interrupters in closed condition, tripping of the circuit interrupter l5 closes the back contacts 13 thereof to trip the circuit interrupter 5|. The circuit interrupter |1 may be interlocked similarly with its network protectors. Such interlock ng is not required, however, for the'circuit interrupter 39 and network protectors of the feeder circuit 35.

In prior artelectrical generating stations, the

. feeder circuit 95, transformer 31, and circuit interrupter 99 generally are available. For this reason, the application of the network system thereto may be in accordance with the embodiment illustrated in Fig. 1. In new insta lations, however, the transformer 31 and feeder circuit 35 may be omitted, if desired. Such omissions result in a system similar to that illustrated in Fig. 3. Referring to Fig. 3, the electrical generators and 9 are associated with the power bus 5 and the load bus |9 in substantially the same manner illustrated in Fig. 1. The only difference resides in the provision of a circuit interrupter 9| which is positioned between the electrical generator I and the feeder circuit 25.

If both of the generators and 3 of the system illustrated in Fig. 3 are out of service, and it is desired to start the generating station in operation, the circuit interrupter 9| is left in open condition. The circuit interrupters 5 and 39 and the network protectors 3| associated with the generator I are all closed to connect the load bus i9 to the power bus 5. Such connection provides electrical energy for the auxiliary equipment of the generating station and permits the starting of this equipment. When the electrical generator closed and the operation of the system thereafter corresponds to that of the system shown in Fig. l. The circuit interrupter 9| may be of any suitable construction and may be designed for manual control. For the purpose of discussion, it may be'assumed that the circuit interrupter 9| is similar in construction and operation to the circuit interrupter |5 with the exception of the omission of the pallet switch 99 thereof.

If desired, the system of Fig. 3 may include a circuit interrupter 9| for the electrical generator 3. However, for the purpose of discussion, it is assumed that the feeder circuit 25 and associated transformers are sumcient to supply energy to l the auxiliary equipment for both of .the electrical generators. Consequently, the electrical generator 9 may have connections to the power bus 5 and the load bus I 9 which ar similar to those illustrated in F18. 1. I

If a generating station is to be constructed having only one generator installed initially but having provision for subsequent addition of one With both of the or more electrical generators, a construction simi lar to that illustrated in Fig. 4 may be employed. Referring to Fig. 4, the electrical generator I is connected to the power bus S through the transformer I and the circuit interrupters ISA and SIA which correspond to the circuit interrupters IS and SI of Fig. 3. In addition, the electrical generator I and the power bus 5 may be connected through the feeder circuit 25, the network transformers 29, and the network protectors SI to the load bus I8. The feeder circuit 25 includes a feeder circuit interrupter 33A which corresponds to the feeder circuit interrupter 33 of Fig. 3.-

In addition, the electrical generator I is connected through a circuit interrupter 33, feeder circuit 93, network transformers 29, and network protectors SIA to the load bus III. The protectors SI of the feeder circuit 25 are interlocked with the circuit interrupters ISA and 33A to prevent their closure unless both of the circuit interrupters ISA and 33A are closed. The protectors 3i also are interlocked with the circuit interrupters ISA and 33A to trip if either of the circuit interrupters ISA or 33A trips. In a somewhat similar manner, the protectors 3IA, which are similar to the protectors 3! in construction, are interlocked with the circuit interrupters ISA and 9IA to permit closure of the protectors only if both of the circuit interrupters ISA and SIA are closed. If either of the circuit interrupters ISA or SIA trips, the interlocking effects a tripping of the protectors SIA.

Assuming that only the electrical generator I is installed in the generating station illustrated in Fig. 4, the operation of the station may be set forth. If the generating station is to be initially started, the circuit interrupter SIA is in open condition, whereas the circuit interrupters ISA, 33A. and the protectors ii are all closed. This energizes the load bus I9 through the feeder circuit 25 from the power bus S, and permits energization of auxiliary equipment in the generating station. When the generator I is in condition to supply electrical energy to the power bus S, the circuit interrupter SIA is closed. In addition, the circuit interrupter 33 and the protector SIA are closed to energize the load bus IS through the feeder circuit 93. This construction assures a dual source of electrical energy for the load bus I9 when the generating station includes only one electrical generator.

If an additional electrical generator, such as the generator 3, is to be added, the connections for this generator may be similar to those illustrated in Figs. 1 and 3. with both generators installed, the generator cannot be synchronized through the load bus I9. This is for the reason that the protectors 3| of the feeder circuit 2S can be in closed condition only if the circuit in- I terrupters ISA and SSA are in closed condition. Moreover, the protectors SIA may be in closed condition only if the circuit interrupters ISA and SIA are in closed condition. For these reasons,

synchronization of the generators I and I must take place through the power bus I in the modification illustrated in Fig. 4.

A specific construction for the system connecting the electrical generator I to the buses S and II is illustrated in Fig. 5. Except for the arrangement'of pallet switches, the circuit interrupters ISA and SIA may be similar to the circuit interrupters IS and SI of Fig. 3. The feedercircuit-interrupter SSA also is similar to the feeder-circuit-interrupter S8 of Figs. 1 to 3 excep interlocking the network protectors 3| with the circuit interrupter; ISA and "A, the circuit interrupter ISA is provided with a pallet switch IIII having front contacts I01 and back contacts IBS. In addition, the circuit interrupter "A is provided with a pallet switch I01 having front contacts I09 and back contacts II I. By inspection of Fig. 5, it will be observed that the closinB contacts 63 of the master relay are connected in series with the front contacts I09 and III! of the pallet switches I01 and IIII for controlling the energization of the closing relay S'I. Consequently, if either pair of contacts III! or III is open. the circuit interrupter SI of Fig. 5 cannot close.

Inspection of Fig. 5 also reveals the fact that the tripping contacts SS of the master relay SI associated with the protector 8| are connected in parallel with the back contacts IIIS and III of the circuit interrupters ISA and 33A. Consequently, the tripping of either of the circuit Interrupters ISA or 33A results in the tripping of the circuit interrupter SI.

In a somewhat similar manner, the network protector 3IA is associated with a pallet switch on the circuit interrupter SIA having front contacts I I3 and back contacts I IS, and with a pallet switch on the circuit interrupter I SA having front contacts Ill and back contacts H9. The tripping contacts 65 of the master. relay SI associated with the network protector 3| A are connected in parallel with the back contacts I I S and I I9 of the circuit interrupters BIA and ISA. Consequently, tripping of eitherof these circuit interrupters results in a tripping operation of the circuit interrupter SI located in the network protector HA.

The closing contacts 63 of the master relay SI employed for the network protector 3 IA are connected in series with the front contacts H3 and [I1 of the circuit 'interrupters 9IA and ISA. Therefore, the circuit interrupter SI of the network protector SIA cannot close unless both of the circuit interrupters ISA and QIA are closed. It will be understood that each of the network protectors 3| associated with one of the feeder circuits 2S or 21 is interlocked in the same manner with the related circuit interrupters. Also, each of the network protectors SIA is interlocked in the same manner with pallet switches provided on the circuit interrupters SIA and ISA.

Although the invention has been described with reference to certain specific embodiments thereof, numerous modifications are possible. Therefore, the invention is to be restricted only by the appended claims.

I claim as my invention:

1. In an electrical system, a power-bus, a plurality of electrical generators, means for connecting and disconnecting each of said electrical generators with respect to said power-bus, a loadbus, means for connecting said load-bus to said power-bus, means independent of said power-bus for connecting said load-bus selectively to either or to both of said electrical generators, and means permitting connection of said load-bus to said power-bus and to one of said electrical generators only if said one electrical generator is connected to said power-bus.

2. In an electrical system, a power-bus, a plurality of electrical generators, transformer means for coupling each of said generators to said power bus, circuit-interrupting-means controlling the for the pallet switch arrangement thereonl For connection of each of said generators to said power-bus through the associated transformer means, a load-bus, means for connecting said load-bus selectively toeithe'r or to both of said generators on the generator sides of the associated transformer means, and means permitting connection of said load-bus to one of said generators only if said one generator is connected to said power-bus.

3. In an electricalsystem, a power-bus, a plurality of electrical generators,transformer means for coupling each of said generators to said power bus, circuit-interrupting-means controlling the connection of each of said generators to said power-bus through the associated transformer means, a load-bus, means for connecting said load-bus selectively to either or to both of said generators on the generator sides of the associated transformer means, means responsive to the condition of said last-named connecting means when a fault occurs thereon for inter-, rupting the connection of said load-bus to one of said generators through the faulty connecting means, and means permitting connection of said load-bus to one of said generators only if said one generator is connected to said power-bus.

4. In an electrical system, a power-bus, a plurality of electrical generators, means including a transformer and a first circuit-interrupter for coupling each of said generators to said power bus, a load-bus, and means for connecting each of said generators to said load-bus, at least one of said last-named means including a feeder circuit connected to the associated generator on the generator side of the associated first circuitinterrupter, a second circuit-interrupter in the feeder circuit for controlling the connection of the feeder circuit to said load-bus, and means permitting closure of said second circuit-interrupter only when the associated first circuitinterrupter is closed, whereby said generators cannot be synchronized through said load-bus.

5. In an electrical system, a power-bus, a plurality of electrical generators, means including a transformer and a first circuit-interrupter for coupling each of said generators to said power bus, a load-bus and means for connecting each of said generators to said load-bus, each of said last-named means including a feeder circuit connected to the associated generator on the generator side of the associated circuit-interrupter, a load-bus transformer, a second circuit-interrupter in the feeder circuit for controlling the connection of the feeder circuit to said load-bus through said load-bus transformer, means responsive to the direction of power flow therethrough for tripping said second circuit-interrupter, and means permitting closure of said second circuit interrupter only when the associated first circuit-interrupter is closed, whereby said generators cannot be synchronized through said load-bus.

6. In an electrical system, a power-bus, a plurality of electrical generators, means including a transformer and a first circuit-interrupter for coupling each of said generators to said power bus, a load-bus, means including a connecting circuit extending between said power-bus and said load-bus for transmitting power therebetween, circuit-breaker-means for controlling the connection of said power-bus to said load-bus through said connecting circuit, means responsive to the direction of power fiow therethrough for tripping said circuit-breaker-means,' and means for connecting each of said generators to said load-bus, each of said last-named means including a feeder circuit connected to the associated generator on the generator side of the associated circuit-interrupter, a second circuit-interrupter in the feeder circuit for controlling the connection of the feeder circuit to said load-bus, and means permitting closure of said second circuit- "interrupter only when the associated first circuit-interrupter is closed, whereby said generators cannot be synchronized through said loadcuit-interrupter for connecting each of said secondary windings to said power-bus, a separate electrical generator connected to each of said primary windings for supplying power through said'transformers to said power-bus, a load-bus,

a first feeder circuit for supplying energy from said power-bus to said load-bus, means includin a transformer and a. circuit-breaker connecting said feeder circuit to said power-bus, means including a transformer and a circuit-breaker for connecting said feeder circuit to said load-bus, and means for connecting each of said generators to said load-bus, each of said last-named means comprising a second feeder circuit connected to the associated generator on the generator side of the associated power transformer, means including a transformer and a second circuit-interrupter for connecting said second feeder circuit to said load-bus, means responsive to the direction of power fiow through said second circuitinterrupter for tripping said second circuit-interrupter, and means responsive to a tripped condition of thevassociated first-circuit-interrupter for maintaining said second circuit interrupter in tripped condition.

8. In an electrical system, a power-bus, a plurality of electrical generators, means including a transformer and a first circuit-interrupter for coupling each of said generators to said powerbus, 2. load-bus, means for connecting each of said generators to said load-bus, each of said lastnamed means including a feeder circuit connected to the associated generator on the generator side of the associated circuit-interrupter, a second circuit-interrupter in the feeder circuit for controlling the connection of the feeder circuit to said load-bus, means permitting closureof said second circuit interrupter only when the associated first circuit-interrupter is closed, whereby said generators cannot be synchronized through'said load-bus, and circuit-interruptermeans intermediate one of said generators and its associated feeder circuit, whereby said load-bus may be energized from said power-bus when all of said generators are disconnected therefrom.

9. In an electrical system, a power-bus, a plurality of electrical'generators, means including a transformer and a first circuit-interrupter for coupling each of said generators to said power bus, a load-bus, and means for connecting each of said generators to said load-bus, each of said last-named means including a feeder circuit connected to the associated generator on the gener ator side of the associated circuit-interrupter, a load-bus transformer, a second circuit-interrupter in the feeder circuit for controlling the connection of the feeder circuit to said load-bus through said load-bus transformer, means responsive to the direction of'power fiow therethrough for tripping said second circuit-interrupter, means permitting closure of said second circuit-interrupter only when the associated first circuit-interrupter is closed, whereby said generators cannot be synchronized through said loadbus, and circuit-interrupting-means intermediate one of said generators and its associated feeder circuit, whereby said load-bus may be energized from said power-bus when all of said generators are disconnected therefrom.

10. In an electrical system, an electrical generator, a power-bus, means for connnectlng said electrical generator to said power-bus, a load-bus, and means for energizing said load-bus from either said power-bus or said electrical generator, said last-named means comprising a feeder circuit, means for connecting a first end of said feeder circuit selectively to said power-bus or to both power-bus and said electrical generator, means connecting a second end of said feeder circuit to said load-bus, and means permitting connection of said feeder circuit to said electrical generator only when said electrical generator is connected to said power-bus.

11. In an electrical system, an electrical generator, a power-bus, transformer means, means for connecting said electrical generator to said power-bus through said transformer means, a load-bus, and means for energizing said load-bus from either said power-bus or said electrical generator, said last-maimed means comprising a feeder circuit, means for connecting a first end of said feeder circuit selectively to said power-bus through said transformer means to both said power-bus through said transformer means and said electrical generator, means connectinga second end of said feeder circuit to said load bus, means permitting connections of said feeder circuit to said electrical generator only when said electrical generator is connected to said powerbus, a second feeder circuit, means connecting a first end of said second feeder circuit to said electrical generator, and means connecting a second end of said second electrical generator to said load-bus for energizing said load-bus independently of said first feeder circuit.

12. In an electrical system, an electrical generator, a power-bus, transformer means, means for connecting said electrical generator to said power-bus through said transformer means, a load-bus, and means for energizing said load-bus from either said power-bus or-said electrical generator, said last-named means comprising a feeder circuit, means for connecting a first end of said feeder circuit selectively to said power-bus through said transformer means or to both said power-bus through said transformer means and said electrical generator, means connecting a second end of said feeder circuit to said load bus, means permitting connections of said feeder circuit to said electrical generator only when said electrical generator is connected to said powerbus, a second feeder circuit, means connecting a first end of said second feeder circuit to said electrical generator, means connecting a second end of said second feeder circuit to said load-bus for energizing said load-bus independently of said first feeder circuit, and means permitting connection of said load-bus throuflh said second feeder circuit to said electrical generator only when said electrical generator is connected to said power-bus.

13. In an electrical system, an electrical generator, a power-bus, transformer means, means for connecting said electrical generator to said power-bus through said transformer means, a load-bus. and means for energizing said loadbus from either said power-bus or said electrical generator, said last-named means comprising a feeder circuit, means for connecting a first end of said feeder circuit selectively to said power-bus through said transformer means or both said power-bus through said transformer means and said electrical generator, means connecting a second end of said feeder circuit to said load bus. means permitting connection of said feeder circuit to said electrical generator only when said electrical generator is connected to said power-bus, a second feeder circuit, means connecting a first end of said second feeder circuit to said electrical generator, and means connecting a second end of said second feeder circuit to said load-bus for energizing said load-bus independently of said first feeder circuit, said means for connecting. said transformer, second circuit-interrupting-means for controlling the connection of said transformer to said power-bus, a load-bus, and means for energizing said load-bus from either said power-bus or said electrical generator, said last-named means comprising a first feeder circuit, third circuit-interrupting-means connecting a first end of said first feeder circuit to a point intermediate said first circuit-interrupting-means and said transformer, transformer means for coupling a second end of said first feeder circuit to said ioadbus, fourth circuit-luteHunting-means controlling the connection of said transformer means to said load-bus, means permitting said fourth circuit-interrupting-means to be in closed condition only when said second and third circuit-interrupting-means are in closed condition, a second feeder circuit having a first and connected between said electrical generator and said first circuit-interrupting-means, transformer means for coupling a second end of said second feeder circuit to said load bus, fifth circuit-interrupting-means controlling the connection of said last-named transformer means to said load-bus, and means permitting said fifth circult-interrupting-means to be in closed condition only when said first and second circuit-interrupting-means are in closed condition.

. ALEXANDER. C. MONTEI'IH. 

